Resolving hydrogen atoms at metal-metal hydride interfaces

Hydrogen as a fuel can be stored safely with high volumetric density in metals. It can, however, also be detrimental to metals causing embrittlement. Understanding fundamental behavior of hydrogen at atomic scale is key to improve the properties of metal-metal hydride systems. However, currently, there is no robust technique capable of visualizing hydrogen atoms. Here, we demonstrate that hydrogen atoms can be imaged unprecedentedly with integrated differential phase contrast, a recently developed technique performed in a scanning transmission electron microscope. Images of the titanium-titanium monohydride interface reveal remarkable stability of the hydride phase, originating from the interplay between compressive stress and interfacial coherence. We also uncovered, thirty years after three models were proposed, which one describes the position of the hydrogen atoms with respect to the interface. Our work enables novel research on hydrides and is extendable to all materials containing light and heavy elements, including oxides, nitrides, carbides and borides

Pacemaker and ICD Troubleshooting

Continuous advancements in technology and software algorithms for pacemakers and implantable cardioverter‐defibrillators (ICDs) have improved functional reliability and broadened their diagnostic capabilities. At the same time, understanding management and troubleshooting of modern devices has become increasingly complex for the device implanter. This chapter provides an overview of the underlying physics and basic principles important to pacemaker and ICD function. The second part of this chapter outlines common device problems encountered in patients with pacemakers and ICDs and provides solutions and tips for troubleshooting

Real space imaging of hydrogen at a metal - metal hydride interface

Hydrogen as a prospective fuel can be stored safely with high volumetric density in metals. It can, however, also be detrimental to metals causing embrittlement. For a better understanding of these metal-metal hydride systems, and in particular their interfaces, real-space imaging of hydrogen with atomic resolution is required. However, hydrogen has not been imaged before at an interface. Moreover, to date, a robust technique that is capable to do such light-element imaging has not been demonstrated. Here, we show that integrated Differential Phase Contrast (iDPC), a recently developed imaging technique performed in an aberration corrected scanning transmission electron microscope, has this capability. Atomically sharp interfaces between hexagonal close-packed titanium and face-centered tetragonal titanium monohydride have been imaged, unambiguously resolving the hydrogen columns. Exploiting the fact that this monohydride has two types of columns with identical surrounding of the host Ti atom we have, 30 years after they were first proposed, finally resolved which one of the proposed structural models holds for the interface. Using both experimental and simulated images, we compare the iDPC technique with the currently more common annular bright field (ABF) technique, showing that iDPC is superior regarding complicating wave interference effects that may lead to erroneous detection of light element columns

Real space imaging of hydrogen at a metal - metal hydride interface

Hydrogen as a prospective fuel can be stored safely with high volumetric density in metals. It can, however, also be detrimental to metals causing embrittlement. For a better understanding of these metal-metal hydride systems, and in particular their interfaces, real-space imaging of hydrogen with atomic resolution is required. However, hydrogen has not been imaged before at an interface. Moreover, to date, a robust technique that is capable to do such light-element imaging has not been demonstrated. Here, we show that integrated Differential Phase Contrast (iDPC), a recently developed imaging technique performed in an aberration corrected scanning transmission electron microscope, has this capability. Atomically sharp interfaces between hexagonal close-packed titanium and face-centered tetragonal titanium monohydride have been imaged, unambiguously resolving the hydrogen columns. Exploiting the fact that this monohydride has two types of columns with identical surrounding of the host Ti atom we have, 30 years after they were first proposed, finally resolved which one of the proposed structural models holds for the interface. Using both experimental and simulated images, we compare the iDPC technique with the currently more common annular bright field (ABF) technique, showing that iDPC is superior regarding complicating wave interference effects that may lead to erroneous detection of light element columns